KR101549501B1 - Head steak assembly and method of manufacturing the same - Google Patents

Abstract

Wherein the head stack assembly includes an opening in the actuator arm-actuator arm, a head suspension assembly including the load beam, the load beam including a mounting area having an opening, and a head suspension assembly adapted to attach the head suspension assembly to the actuator arm The base plate includes a boss tower having an outer surface and a swaging hole. To increase the compression between the boss tower and the actuator arm opening in the roll direction, rather than in the pitch direction, one of the actuator arm opening, boss tower outer surface, or swaging hole is non-circular. Methods for manufacturing boss towers are also provided.

Description

[0001] HEAD STACK ASSEMBLY AND METHOD OF MANUFACTURING THE SAME [0002]

[0001] Hard disk drive systems (HDDs) typically include one or more data storage disks. A conversion head carried in the slider is used for reading from and writing to a data track on the disc. The slider is held in a suspension assembly including an arm assembly including an actuator arm.

[0002] Swaging processes are common material processing techniques used to connect suspension assemblies to actuator arms. The suspension assembly includes a boss tower configured to fit within an opening in the actuator arm. When the swage ball passes through the boss tower when it is aligned with the female opening, the boss tower expands and contacts the opening surface and creates frictional engagement to connect the suspension assembly to the actuator arm.

[0003] One specific embodiment of the present disclosure relates to a head stack assembly comprising: a head suspension assembly including a load beam, the actuator arm having an opening in the actuator arm- The beam including a mounting region with an opening and a base plate adapted to attach the head suspension assembly to the actuator arm, the base plate including a boss tower having an outer surface and a swaging hole . One of the actuator arm opening, boss tower outer surface, or swaging hole is non-circular.

These and various other features and advantages will be apparent from a reading of the following detailed description.

BRIEF DESCRIPTION OF THE DRAWINGS [0005] The invention will be more fully understood from the following detailed description of various embodiments of the invention in connection with the accompanying drawings,
[0006] FIG. 1 is a perspective view of an exemplary hard disk drive (HDD) system.
[0007] Figure 2 is a perspective view of a disassembled head stack assembly.
[0008] FIG. 3 is a side view of a base plate, a load beam, and an actuator arm prior to swaging.
[0009] FIG. 4 is a top plan view of a base plate, a load beam, and an actuator arm
[0010] FIG. 5 is a plan view of a base plate and actuator arms, in accordance with one embodiment of the present disclosure.
[0011] FIG. 6 is a plan view of a base plate and actuator arms, according to another embodiment of the present disclosure
[0012] Figure 7 is a plan view of a base plate and actuator arms, according to another embodiment of the present disclosure
[0013] Figures 8A-8H are plan views of various embodiments of base plates in accordance with the present disclosure.
[0014] Figures 9A-9I are plan views of various embodiments of actuator arms, in accordance with the present disclosure.
[0015] Figures 10A-10B are top views of various embodiments of base plates according to the present disclosure.
[0016] Figures 11A-11C are examples of "circular-in-nature" shapes.

[0017] The present invention relates to disk drives. More specifically, the present invention provides a head-gimbal assembly that is attached to an actuator arm by a swaging process. By way of example only, the present invention applies to hard disk devices, but it will be appreciated that the present invention has a much broader applicability.

[0018] The swaging process is a material processing technique used to connect various elements; For hard disk devices, swaging is typically used to form the head stack assembly. During the process, the boss tower expands to couple the load beam of the head gimbal assembly to the E-block or actuator arm. According to the present disclosure, at least one of the head stack assembly engaging surfaces (i.e., boss tower outer surface, boss tower swage hole or actuator arm opening) is non-circular. The non-circular engagement surface produces unequal compressive forces in the pitch and roll directions, thereby reducing bending and distortion of the actuator arm, which is often experienced when swaging circular engagement surfaces. As a result, the overall quality of the head stack assembly is improved due to the reduced distortion (e.g., up or down bending) of the actuator arms.

[0019] In the following description, reference is made to the accompanying drawings, which form a part hereof, and in which is shown by way of illustration, at least one specific embodiment. The following description provides additional specific embodiments. It is to be understood that other embodiments may be contemplated and configured without departing from the scope or spirit of the invention. Accordingly, the following detailed description is not to be taken in a limiting sense. Unless the present invention so restricts, recognition of the various aspects of the present invention will be obtained through discussion of the examples provided below.

[0020] As used herein, the singular forms "a", "an", and "the" include plural embodiments having plural referents unless the context clearly dictates otherwise. As used in this specification and the appended claims, the term "or" is generally used to mean "and / or" in its sense, unless the context clearly dictates otherwise.

[0021] FIG. 1 illustrates at least one magnetic storage disk 22 configured to rotate about a shaft 24, an actuation motor 26 (eg, a voice coil motor), an actuator arm An exemplary hard disk drive (HDD) system (not shown), including a suspension assembly 30 including a load beam, a slider 32, and a slider 32 carrying a conversion or read / write head 20). The slider 32 is supported by the suspension assembly 30 and consequently supported by the actuator arm 28 in turn. The actuator arm 28, the suspension assembly 30 and the slider 32 together form a head stack assembly HSA. The drive motor 26 drives the actuator arm 28 about the axis 34 so that the suspension 30 and the slider 32 sweep in an arc across the surface of the rotating disk 22. [ And the slider 32 is "sliding" or " flying "across the disk 22 on an air cushion of air, often referred to as an air bearing. The read / write head held in the slider 32 can be positioned with respect to selected concentric data tracks 36 of the disk 22 by piezoelectric micro-actuators not shown in Fig. The stack of co-rotating discs 22 is provided with additional actuators arms 28, suspension assemblies 30, and readouts at the top and bottom surfaces of each disc 22 in the stack, It should be noted that sliders 32 may be provided that have read / write heads for writing. The structure with multiple actuator arms 28, suspension assemblies 30, and slider 32 is often referred to as an E-block.

[0022] The present disclosure provides an attachment system for creating a head stack assembly (HSA) of the HDD system 20; That is, the disclosure provides a system for attaching various elements together forming HSA.

2 shows an exploded, isometric (not shown) side view of the head stack assembly (HSA) 40, including a base plate 44 having a load beam 42, an actuator arm 28 and a boss tower 46. [ It is an isometric view. In the illustrated embodiment, the HSA 40 includes a flexure 50 to which a slider 32 holding a transducing or read / write head is mounted; The flexure 50 may be attached to the load beam 42 or incorporated into the load beam 42 by any conventional mechanism. In some embodiments, the load beam 42, the flexure 50, and the slider 32 are collectively referred to as a head suspension assembly. The flexure 50 allows for their pitch and roll motion when the slider 32 and the read / write head move over the data tracks 36 of the disk 22 (of FIG. 1).

The load beam 42 includes a mounting section 52 at the proximal end, a rigid section 54 near the distal end, and a mounting section 52 at the proximal end, And a spring zone 56 between the two ends 54 of the spring. The opening 60 is in the mounting area 52. The spring area 56 is relatively resilient and is a slider 32 having a read / write head near the spinning disk, as opposed to an upward force generated by the air bearing on the disk. To provide a downward biasing force to the distal tip of the load beam 42 to maintain a constant force. The HSA 40 is typically coupled to the drive motor 26 (FIG. 1) through an actuator arm 28 attached to the mounting region 52 of the load beam 42.

A swage-type attachment is used to couple the load beam 42 (at the mounting area 52) to the actuator arm 28. The opening 58 of the actuator arm 28 and the opening 60 of the load beam 42 are sized and sized to receive the boss tower 46 of the base plate 44 therethrough. The boss tower 46 has a swaging opening or hole 48 and an outer surface 64 through the boss tower 46 and the base plate 44. In some embodiments, the overall height of the exterior surface 64 is perpendicular to the base from which the boss tower 46 extends.

In order to swing the load beam 42 to the actuator arm 28, the actuator arm 28, the load beam 42 and the base plate 44 are fixed to the load beam opening 60 and the actuator arm opening 58 (Not shown). 3, the mounting area 52 is defined by the base plate 44 (specifically, the surface 62 of the base plate 44) and the actuator arm 28 (specifically, the surface of the arm 28) (63). The outer surface 64 of the boss tower 46 is sized to fit within the interior surface 68 of the opening 58 of the actuator arm 28. The outer surface 64 is typically adjacent the inner surface 68, although the amount of engagement may vary prior to swaging.

Thereafter, one or more swaging balls 70 (FIG. 3) are lowered through the swage holes 48 to expand the boss towers 46 in the actuator arm openings 58. This extension creates a frictional attachment interface between the outer surface 64 of the boss tower 46 and the inner surface 68 of the actuator arm opening 58. In some embodiments, friction attachment may also occur at the load beam opening 60.

When passing through the swage hole 48 and the openings 58 and 60, the swaging ball 70 typically has an inner surface of the swage hole 48 (which is the inner surface of the boss tower 46) Thereby creating a force directed outwardly against the surface and deforming the boss tower 46 to cause the outer surface 64 to frictionally engage the inner surface 68 of the female opening 58. In the event that the swage hole 48 and the swaging ball 70 are symmetrical, the force will radiate outward in a concentric manner. Thereafter, a larger diameter swaging ball 70 may be used to further expand the boss tower 46 and increase the coupling between the surface 64 and the surface 68.

4 illustrates an enlarged view of a portion of the HSA 40 having an actuator arm 28 connected to the load beam 42 via the boss tower 46 of the base plate 44. 4, the assembly 40 includes an axis (referred to as the y-axis) in the lateral direction y that intersects the center of the boss tower 46 and the swage hole 48, longitudinal axis x axis (referred to as the x-axis).

[0030] According to the present disclosure, a surface that forms a swaged frictional fit between a boss tower (e.g., boss tower 48) and an actuator arm (e.g., arm 28) Are different; That is, prior to swaging, either the surface of the actuator arm or the surface of the boss tower is not circular. For example, the boss tower outer surface (e.g., surface 64) may be non-circular and the inner surface (e.g., inner surface 68) of the female opening may be circular. Another example has a non-circular boss tower swage hole surface (e.g., hole 48) and an inner surface (e.g., inner surface 68) of a circular female opening. The boss tower outer surface (e.g., surface 64) may have the same or different shape as the corresponding swage hole (e.g., swage hole 48); That is, both of them may be non-circular or only one may be non-circular. As another example of other shaped contact surfaces, the inner surface (e.g., inner surface 68) of the female opening may be non-circular and the boss tower outer surface (e.g., surface 64) . Two surface shapes are selected to reduce the interference of the boss tower with the female orifices, which are different in the pitch direction (i.e., the x-direction) and the roll direction (i.e. the y-direction), during swaging and after swaging Thereby generating a compressive force.

[0031] Figures 5-7 illustrate three embodiments of suspension assemblies, or portions thereof, wherein one of the surfaces forming the swaged friction fit is non-circular. In each of these embodiments, the non-circular surface in plan view is egg-shaped and produces reduced compression in the longitudinal direction (x-direction) of the arm when swaged.

In FIG. 5, the actuator arm 128 has a circular opening 158 into which a boss tower 146 of the base plate 144 is inserted. The boss tower 146 has a circular swage hole 148 but has a non-circular outer surface 164. The outer surface 164 has an oval or oval shape in which the longer axis of the shape extends laterally in the y-direction. Thus, the wall between the swage hole 148 and the outer surface 164 has a varying thickness around the boss tower 146.

In FIG. 6, the actuator arm 228 has a non-circular opening 258 into which a boss tower 246 of the base plate 244 is inserted. The boss tower 246 has a circular swage hole 248 and a circular outer surface 264 and the wall thickness of the boss tower 246 is constant around the boss tower 246. The opening 258 has an oval or elliptical shape in which the longer axis of the shape extends longitudinally in the x-direction.

In FIG. 7, the actuator arm 328 has a circular opening 358 into which a boss tower 346 of the base plate 344 is inserted. The boss tower 346 has a circular outer surface 364, but has a non-circular swage hole 348. Swage hole 348 has an oval or oval shape in which the longer axis of the shape extends in the longitudinal direction in the x-direction. As in FIG. 5, the wall between swage hole 348 and outer surface 364 has a variable thickness.

[0035] Non-illustrated but alternative suitable configurations include a boss tower having a non-circular swage hole (e.g., oval or oval) and a corresponding non-circular outer surface so that the wall thickness of the boss tower is constant Lt; / RTI > The longer axis of the non-circular boss tower extends in the transverse direction in the y-direction. Such a boss tower having a circular opening in the actuator arm will be used.

[0036] The non-circular shape in any of the boss tower swage hole, boss tower outer surface, or actuator arm opening is determined by the pitch direction (longitudinal or x-direction in FIGS. 5-7) and the roll direction To produce asymmetric coupling of the boss tower and the actuator arm holes, which produces different compressive forces in the transverse or y-direction in Fig. Although the preferred non-circular shape is oval or oval, other non-circular shapes that are symmetrical and non-symmetric, regular and irregular may be used. Figs. 8A-8H, Figs. 9A-9I and Figs. 10A and 10B illustrate various alternative non-circular shapes for boss tower mating surfaces.

[0037] Figures 8a-8h illustrate eight different suitable shapes for the outer surface of the boss tower. The following elements are present in each of these drawings: an actuator arm 444, a boss tower 446, a swage hole 448 in the boss tower, and an outer surface 464 of the boss tower. Elements are distinguished between different drawings by an alphabetic indicator following the number; For example, in FIG. 8A, each of the numbers indicating the element ends in "A ", and in FIG. 8B, each of the numbers indicating the element ends with" B ", but exceptionally, Swage hole 448 is always the same and therefore does not include any alphabetic indicator. These exemplary boss tower shapes, when incorporated into the head stack assembly (e.g., the HSA 40 of Figs. 2 and 4), have a symmetrical shape in both the longitudinal direction of the arms and the transverse direction of the arms, Symmetrical in the transverse direction of the arm but symmetrical in the transverse direction of the arm but asymmetrical in the longitudinal direction of the arm and an asymmetric shape in both the longitudinal direction of the arm and the transverse direction of the arm .

Referring now to the drawings, each of Figures 8A-8H illustrates a base plate 444A-H having a circular swage hole 448 and a non-circular outer surface 464A -H), which results in a wall having a non-uniform thickness around the boss tower. 8A, 8B and 8C illustrate examples of boss tower engaging surfaces that are symmetrical about a longitudinal axis through the final suspension assembly to which the base plate is to be integrated and the swage hole of the base plate.

8A shows a base plate 444A having a boss tower 446A having a circular swage hole 448 and a non-circular outer surface 464A ; In this embodiment, surface portion 465A has an arcuate contour that provides a non-circular shape to outer surface 464A. Surface portion 465A occupies approximately one-third of distal-most outer surface 464A and is defined as a radius different from the radius of the other two-thirds of outer surface 464A. The boss tower 446A at the surface portion 465A has a thickness less than the remaining two-thirds of the boss tower 446A. The thinner portion of the boss tower 446A (at surface portion 465A) is symmetrical about the longitudinal extent of the final suspension assembly and base plate 444A to be integrated. 8B shows a base plate 444B having a boss tower 446B having a circular swage hole 448 and a non-circular outer surface 464B; In this embodiment, the arcuate surface portion 465B provides a non-circular shape to the outer surface 464B. The surface portion 465B occupies approximately one-third of the proximal-most outer surface 464B and is defined as a radius different from the remaining two-thirds of the outer surface 464B. The boss tower 446B at the surface portion 465B has a lesser thickness at the other two thirds of the boss tower 446B. The thinner portion of the boss tower 446B (at surface portion 465B) is symmetrical about the longitudinal extent of the final suspension assembly and base plate 444B to be integrated. 8c, which is an accumulation of two previous examples, shows a base plate 444C having a boss tower 446C with a non-circular outer surface 464C; In this embodiment, the two arcuate surface portions 465C and 465C 'provide a non-circular shape to the outer surface 464C. Surface portion 465C occupies approximately one-third of the most distal outer surface 464C and surface portion 465C 'occupies approximately one third of the proximal outer surface 464C. The two surface portions 465C and 465C 'are defined as radii different from the radius of the remaining one third of the outer surface 464C. The boss tower 446C at the surface portions 465C and 465C 'has a thickness less than the remaining 1/3 of the boss tower 446C. The thinner portion of the boss tower 446C is symmetrical about the longitudinal direction of the final suspension assembly and the base plate 444C to be integrated and is symmetrical about the transverse direction of the swage hole 448 in the transverse direction of the final suspension assembly and base plate 444C It is symmetrical around the center. In all of Figs. 8A, 8B and 8C, when integrated and swaged into the actuator arm opening, the compression will be reduced in the longitudinal or pitch direction due to the non-circular boss tower.

[0040] Figures 8d, 8e, and 8f illustrate examples of boss tower engaging surfaces that are symmetrical about the transverse axis through the final suspension assembly to which the base plate is to be integrated and the swage holes of the base plate. Further, Figure 8F illustrates an exemplary base plate that is also symmetrical about a longitudinal axis.

[0041] Figure 8d shows a base plate 444D having a boss tower 446D having a circular swage hole 448 and a non-circular outer surface 464D; In this embodiment, the surface portion 465D has an arcuate contour providing a non-circular shape to the outer surface 464D. Surface portion 465D occupies approximately one third of outer surface 464D and is defined as a radius different from the remaining two thirds of outer surface 464D. The boss tower 446D at the surface portion 465D has a thickness less than that at the other two thirds of the boss tower 446D. The thinner portion of the boss tower 446D (at the surface portion 465D) is symmetrical about the transverse axis through the center of the swage hole 448. 8E illustrates the mirror image of FIG. 8D, with the base plate 444E having a boss tower 446E having a circular swage hole 448 and a non-circular outer surface 464E; In this embodiment, the arcuate surface portion 465E occupies approximately one-third of the boss tower 446E and produces less thickness than the remaining two-thirds of the boss tower 446E. The thinner portion of boss tower 446E is symmetrical about the transverse axis through the center of swage hole 448. [ Figure 8f is a combination of the two previous examples and shows the base plate 444F which includes a boss tower 446F having a circular swage hole 448 and a non-circular outer surface 464F ; In this embodiment, the two arcuate surface portions 465F and 465F 'provide a non-circular shape to the outer surface 464F. The surface portion 465F occupies approximately one third of the outer surface 464F and the surface portion 465F 'approximately occupies another third of the outer surface 464F. The two surface portions 465F, 465F 'are defined as radii different from the radius of the remaining one third of the outer surface 464F. The boss tower 446F at the surface portions 465F, 465F 'has a thickness less than at the third of the boss tower 446F. The thinner portion of the boss tower 446F is symmetrical about the final suspension assembly to be integrated and about the longitudinal direction and symmetrical about the center of the swage hole 448 in the transverse direction. In all of Figures 8d, 8e and 8f, when integrated and swaged into the actuator arm opening, the compression will be reduced in the transverse or roll direction due to the non-circular boss tower.

[0042] FIG. 8G shows the two couplings of FIGS. 8C and 8F, both of which are symmetrical in the transverse and longitudinal directions. 8G shows a base plate 444G having a boss tower 446G having a circular swage hole 448 and a non-circular outer surface 464G; In this embodiment, there is no portion of the circular outer surface 464G, rather, the outer surface 464G is formed of four arcuate segments. The boss tower 446G is symmetrical about the final suspension assembly and longitudinal direction to be integrated and symmetrical about the center of the swage hole 448 in the transverse direction.

8h is similar to FIG. 8g in that base plate 444H has a boss tower 446H having an outer surface 464H and a circular swage hole 448, wherein there is no circular portion, Rather, outer surface 464H is formed of three arcuate segments. As illustrated, boss tower 446H is symmetrical about the transverse axis through the center of swage hole 448. The three arcuate segments forming the outer surface 464H may alternatively be configured to have a boss tower that is symmetrical about the longitudinal axis or asymmetric about the circumference of both the transverse and longitudinal axes.

[0044] Previous examples (FIGS. 8A-8H) illustrate embodiments having a non-circular boss tower outer surface. As previously indicated, there may be a non-circular shape in any of the mating surfaces (i.e., boss tower outer surface, boss tower swage hole or actuator arm opening). The following examples, Figures 9A-9I, each show an actuator arm 428A-I having a non-circular opening 458A-I. Figures 9a and 9b illustrate examples of boss tower engagement surfaces (specifically, actuator arm openings) that are symmetrical about a longitudinal axis through a final suspension assembly and an actuator arm into which the arm is to be integrated. Figures 9d and 9e illustrate examples of boss tower engagement surfaces (specifically, actuator arm openings) that are symmetrical about the transverse axis axis through the actuator arm opening. Figures 9c, 9f, and 9g illustrate examples of boss tower engagement surfaces (specifically, actuator arm openings) that are symmetrical about the longitudinal axis through the actuator arm and the transverse axis through the actuator arm opening.

[0045] Specifically, FIG. 9A shows an actuator arm 428A having a non-circular opening 458A; In this embodiment, portion 455A of opening 458A has an arcuate contour providing a non-circular shape to opening 458A. Portion 455A occupies approximately one-third of the proximate side of aperture 458A and is defined as a radius different from the radius of the remaining two-thirds of aperture 458A. The aperture 458A is symmetrical about the longitudinal extent of the final suspension assembly and actuator arm 428A to be integrated. Similarly, Figure 9B shows an actuator arm 428B having a non-circular opening 458B; In this embodiment, portion 455B of opening 458B has an arcuate contour providing a non-circular shape to opening 458B. Portion 455B occupies approximately one third of the distal end of aperture 458B and is defined as a radius different from the radius of the remaining two thirds of aperture 458B. The opening 458B is symmetrical about the longitudinal direction of the final suspension assembly and actuator arm 428B to be integrated. 9C, which is a combination of two previous examples, shows an actuator arm 428C having a non-circular opening 458C; In this embodiment, the two arcuate surface portions 455C and 455C 'provide a non-circular shape to the opening 458C. Portion 455C occupies approximately one-third of the proximal side of opening 458C and portion 455C 'occupies approximately one-third of the distal side of opening 458C. The two portions 455C and 455C 'are defined as radii different from the radius of the remaining 1/3 of the opening 458C. The aperture 458C is symmetrical about the longitudinal extent of the final suspension assembly and actuator arm 428C to be integrated and symmetrical about the center of the aperture 458C in the transverse direction.

Turning to FIG. 9D, FIG. 9D shows an actuator arm 428D having a non-circular opening 458D; In this embodiment, portion 455D of opening 458D has an arcuate contour providing a non-circular shape to opening 458D. Portion 455D occupies approximately one-third of opening 458D and is defined as a radius different from the radius of the remaining two thirds of opening 458D. The opening 458D is symmetrical about the transverse axis taken through the center of the opening 458D. Similarly, Figure 9E shows an actuator arm 428E having a non-circular opening 458E; In this embodiment, portion 455E of opening 458E has an arcuate contour providing a non-circular shape to opening 458E. Portion 455E occupies approximately one third of opening 458E and is defined as a radius different from the radius of the remaining two thirds of opening 458E. The aperture 458E is symmetrical about the transverse axis taken through the center of the aperture 458E. 9F, which is a combination of two previous examples, shows an actuator arm 428F having a non-circular opening 458F; In this embodiment, the two arcuate surface portions 455F and 455F 'provide a non-circular shape to the opening 458F. Portion 455F occupies approximately one third of the first side of opening 458F and portion 455F 'occupies approximately one third of the second side of opening 458F. The two portions 455F and 455F 'are defined as radii different from the radius of the remaining one third of the opening 458F. The aperture 458F is symmetrical about the longitudinal periphery of the final suspension assembly and actuator arm 428F to be integrated and also symmetrical about the center of the aperture 458F in the transverse direction.

[0047] FIG. 9g shows two couplings of FIGS. 9c and 9f, both of which are symmetrical in the transverse and longitudinal directions. Specifically, Figure 9G shows an actuator arm 428G having a non-circular opening 458G; In this embodiment, there is no portion of the circular opening 458G, rather the opening 458G is formed of four arcuate segments. The opening 458G is symmetrical about the final suspension assembly to be integrated and about the longitudinal direction and symmetrical about the center of the opening 458G in the transverse direction.

FIG. 9h is similar to FIG. 9g in that opening 458H of arm 428H does not have a circular portion but rather is formed of three arcuate segments. As illustrated, the aperture 458H is not symmetrical about either the longitudinal axis or the transverse axis. The three arcuate segments forming aperture 458H may alternatively be configured to have a boss tower that is symmetric about the longitudinal axis, symmetrical about the transverse axis, or symmetrical about both of them.

[0049] FIG. 9i illustrates another example of a boss tower engagement surface (specifically, an actuator arm opening) that is symmetrical about a longitudinal axis through a final suspension assembly and an actuator arm into which the arm is to be integrated. In Figure 9i, the actuator arm 428I has a non-circular opening 458I with two arcuate contour portions 455I, 455I 'that provide a non-circular shape to the opening 458I.

[0050] Previous examples (FIGS. 9A-9I) illustrate embodiments with non-circular actuator arm openings. As indicated above, the present invention includes a non-circular shape in any of the head stack assembly engagement surfaces (i.e., boss tower outer surface, boss tower swagehole, or actuator arm opening). The following examples, Figures 10a and 10b, illustrate non-circular swage holes.

[0051] FIG. 10A illustrates a base plate 544A having a boss tower 546A having a non-circular swage hole 548A and a circular outer surface 564A; In this embodiment, swage hole 548A has an elongated shape (e.g., oval or oval) having a longer dimension in the longitudinal direction. The boss tower 546A has a non-uniform (inconsistent) thickness with a lesser thickness in the longitudinal direction. When integrated into the circular actuator arm opening, compression results in increased transverse or roll direction. Figure 10b shows a base plate 544B having a boss tower 546B having a non-circular swage hole 548B and a circular outer surface 564B; In this embodiment, swage hole 548B has a elongate shape (e.g., an oval or oval shape) having a longer dimension in the transverse direction. The boss tower 546B has a non-uniform thickness, with less thickness in the transverse direction. When integrated into the circular actuator arm opening, compression results in increased longitudinal, or pitch, direction.

[0052] As indicated previously, the at least one head stack assembly mating surface is non-circular, and various non-circular shapes for the head stack assembly mating surface have been previously provided. The shapes may be regular, irregular, symmetric or asymmetric. Preferably, although in some embodiments there may be straight lines and / or sharp angles (e.g., the non-circular shape may be square or rectangular, etc., although this is not preferred) . Forms that are "circular-in-nature" are considered "prototypes " for purposes of this disclosure, and non-prototypes are not considered. Examples of shapes that are "substantially circular" are provided in FIGS. 11A-11C, although they are not actually circular. Although each of these shapes have secondary features that remove the shape that is actually circular, the primary shape is circular and thus is "substantially circular. &Quot;

For oval or elliptical shapes, a range of about 1.001: 1 to 1.1: 1 is preferred for a ratio of long axis to short axis; In some embodiments, a range of about 1.0047: 1 to 1.0429: 1 is preferred.

[0054] A substantially non-circular or non-circular shape in any of the head stack assembly engagement surfaces (ie, the boss tower outer surface, the boss tower swage hole, or the actuator arm opening) Which produces different compressive forces in the pitch direction (longitudinal direction) and the roll direction (lateral direction). In some embodiments, the compressive force is preferably higher in the roll direction than in the pitch direction.

[0055] The discussion and various examples relate to non-circular shapes for the head stack assembly engaging surfaces prior to the swaging process. After swaging, i.e., after the swage ball 70 has passed the swage hole 48 and the boss tower 46 (as illustrated and described with reference to Figure 3), the mating surfaces are in contact with the actuator arm 28 Is distorted due to compression of surfaces caused by the swage ball 70 relative to the inner surface 68 of the opening 58 and the boss tower 46. In a swaged assembly, it may not be possible to determine which specific surface (i.e., boss tower outer surface, boss tower swage hole, or actuator arm opening) is non-circular, but the swaged coupling may be non- It is less compressed near the area where the part exists.

It is understood that numerous modifications of the methods of manufacturing the head stack assembly and of the head stack assembly coupling surfaces can be made while maintaining the design of the entire invention and maintaining the scope of the present invention. Numerous alternative design or element features have been mentioned above.

[0057] Thus, embodiments of the "non-circular feature for boss tower coupling" have been disclosed. The implementations described above and other implementations fall within the scope of the following claims. Those skilled in the art will recognize that the invention may be practiced in other embodiments than those disclosed herein. The disclosed embodiments are presented for purposes of illustration and not limitation, the invention being limited only by the following claims.

Claims (16)

A head stack assembly comprising:
Vertical and horizontal directions;
An actuator arm, said actuator arm having an opening;
CLAIMS 1. A head suspension assembly comprising a load beam, the load beam including a mounting region with an opening; And
A base plate adapted to attach the head suspension assembly to the actuator arm, the base plate including a boss tower having an outer surface and a swaging hole,
Wherein the actuator arm opening is an oval or elliptical shape having a major axis extending in the vertical direction,
The swaging hole may have an oval shape or a elliptical shape with its major axis extending in the vertical direction,
Wherein the outer surface of the boss tower has an oval or oval shape in which a vertical axis extends in the horizontal direction,
Head stack assembly. delete The method according to claim 1,
Wherein the one of the actuator arm opening or the boss tower outer surface comprises a ratio of a long axis to a short axis of 1.0047: 1 to 1.0429:
Head stack assembly. delete delete delete The method according to claim 1,
Wherein at least one of the actuator arm opening, the boss tower outer surface, or the swaging hole is symmetrical about the vertical axis,
Head stack assembly. The method according to claim 1,
Wherein at least one of the actuator arm opening, the boss tower outer surface, or the swaging hole is symmetrical about the horizontal axis,
Head stack assembly. The method according to claim 1,
Wherein at least one of the actuator arm opening, the boss tower outer surface, or the swaging hole is symmetrical about the periphery of both the vertical axis and the horizontal axis,
Head stack assembly. A head stack assembly having a roll direction and a pitch direction,
An actuator arm, said actuator arm having an opening;
A head suspension assembly including a load beam, the load beam including a mounting area having an opening; And
A base plate adapted to attach the head suspension assembly to the actuator arm, the base plate including a boss tower having an outer surface and a swaging hole,
Wherein one of the actuator arm opening, the boss tower outer surface, and the swaging hole is an oval or elliptical shape having a long axis extending in the pitch direction,
Wherein the actuator arm, the load beam, and the base plate are aligned and swaged with the boss tower existing through the actuator arm opening and the mounting zone opening, and compression between the boss tower and the actuator arm opening is achieved by the pitch Direction in the roll direction,
A head stack assembly having a roll direction and a pitch direction. delete 11. The method of claim 10,
Wherein one of the actuator arm opening, the boss tower outer surface, or the swaging hole has a ratio of major axis to minor axis of 1.0047: 1 to 1.0429: 1,
A head stack assembly having a roll direction and a pitch direction. delete delete delete A method of swaging a head suspension to an actuator arm in a disk drive,
Providing a head suspension assembly including a load beam, the load beam having a mounting region having an opening;
Providing an actuator arm having an aperture;
Providing a base plate comprising a boss tower having a swaging hole having an inner surface and an outer surface, the actuator arm opening being oval or elliptical with a longitudinal axis extending in the vertical direction of the actuator arm, Is oval or elliptical with a long axis extending in the vertical direction, or the outer surface of the boss tower is oval or oval having a long axis extending in the horizontal direction of the actuator arm;
Positioning an opening in the mounting area of the head suspension assembly concentrically with an opening in the actuator arm;
Inserting the boss tower into the openings of the mounting area and the actuator arm such that the mounting area is positioned between the actuator arm and the base plate; And
Inserting a swaging ball into the swaging hole,
How to swing the head suspension from the disk drive to the actuator arm.

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